Both neural and global androgen receptor overexpression affect sexual dimorphism in the mouse brain

Overexpression of Androgen Receptors Masculinizes 2D:4D Digit Ratios in Mice

Studying the role of the prenatal endocrine environment in humans is challenging due to the ethical and practical considerations of measuring hormone levels of the developing fetus. Because it has been difficult to ascertain whether prenatal androgens contribute to the brain and behavior in humans as it does in non-human species, retrospective markers of prenatal androgens, such as the second-to-fourth finger digit ratio (2D:4D), are of interest to the studying of human behavioral endocrinology. To assess the validity of such markers, laboratory animals have been studied. Some strains of mice have been reported to show a sex difference in 2D:4D, and pharmacological and genetic manipulation of the androgen and estrogen receptors (AR and ER) has implicated a role for prenatal androgens in mediating this sex difference, although there have been conflicting reports. Here, we compared mice with global AR overexpression to mice with wildtype (WT) littermates and mice with neural-specific AR overexpression. We found a sex difference in the right hind paw, such that males had larger digit ratios than females. Regardless of sex, mice with global AR overexpression showed an increase in the right hind 2D:4D ratio compared with both WT and neural-specific AR overexpression mice. These results support a role for non-neural AR in the development of 2D:4D and suggest that increased sensitivity to androgens via increased AR is sufficient to increase the masculinization of digit ratios. Future directions for confirming the validity of 2D:4D as a marker for prenatal androgen exposure are discussed.

Evolution of the androgen receptor: Perspectives from human health to dancing birds

Androgenic hormones orchestrate the development and activation of diverse reproductive phenotypes across vertebrates. Although extensive work investigates how selection for these traits modifies individual elements of this signaling system (e.g., hormone or androgen receptor [AR] levels), we know less about natural variation in the AR sequence across vertebrates. Our knowledge of AR sequence mutations is largely limited to work in human patients or cell-lines, providing a framework to contextualize single mutations at the expense of evolutionary timescale. Here we unite both perspectives in a review that explores the functional significance of AR on a domain-by-domain basis, using existing knowledge to highlight how and why each region might evolve. We then examine AR sequence variation on different timescales by examining sequence variation in clades originating in the Cambrian (vertebrates; >500 mya) and Cretaceous (birds; >65 mya). In each case, we characterize how the receptor has changed over time and discuss which regions are most likely to evolve in response to selection. Overall, domains that are required for androgenic signaling to function (e.g., DNA- and ligand-binding) tend to be conserved. Meanwhile, areas that interface with co-regulatory molecules can exhibit notable variation even between closely related species. We propose that accumulating mutations in regulatory regions is one way that AR structure might act as a substrate for selection to guide the evolution of reproductive traits. By synthesizing literature across disciplines and highlighting the evolutionary potential of specific AR regions, we hope to inspire new avenues of integrative research into endocrine system evolution.